Evaluation of a tobacco prevention programme among teenagers in

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Evaluation of a tobacco prevention programme among teenagers in
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Hedman, L., Andersson, M., Stridsman, C., Rönmark, E. (2015)
Evaluation of a tobacco prevention programme among teenagers in Sweden.
BMJ Open, 5(5)
http://dx.doi.org/10.1136/bmjopen-2015-007673
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Open Access
Research
Evaluation of a tobacco prevention
programme among teenagers in Sweden
Linnéa Hedman,1 Martin Andersson,1 Caroline Stridsman,2 Eva Rönmark1
To cite: Hedman L,
Andersson M, Stridsman C,
et al. Evaluation of a tobacco
prevention programme
among teenagers in Sweden.
BMJ Open 2015;5:e007673.
doi:10.1136/bmjopen-2015007673
▸ Prepublication history for
this paper is available online.
To view these files please
visit the journal online
(http://dx.doi.org/10.1136/
bmjopen-2015-007673).
Received 14 January 2015
Revised 21 April 2015
Accepted 24 April 2015
ABSTRACT
Objective: To study the prevalence of tobacco use
among teenagers, to evaluate a tobacco prevention
programme and to study factors related to participation
in the prevention programme.
Design and setting: Population-based prospective
cohort study.
Method: Within the Obstructive Lung disease in
Northern Sweden (OLIN) studies, a cohort study about
asthma in schoolchildren started in 2006. All children
aged 7–8 years in three municipalities were invited to a
questionnaire survey and 2585 (96%) participated. The
cohort was followed up at age 11–12 years (n=2612,
95% of invited) and 14–15 years (n=2345, 88% of
invited). In 2010, some of the children in the OLIN
cohort (n=447) were invited to a local tobacco
prevention programme and 224 (50%) chose to
participate.
Results: At the age of 14–15 years, the prevalence of
daily smoking was 3.5%. Factors related to smoking
were female sex, having a smoking mother, participation
in sports and lower parental socioeconomic status
(SES). The prevalence of using snus was 3.3% and risk
factors were male sex, having a smoking mother, having
a snus-using father and non-participation in the
prevention programme. In the prevention programme,
the prevalence of tobacco use was significantly lower
among the participants compared with the controls in
the cohort. Factors related to non-participation were
male sex, having a smoking mother, lower parental SES
and participation in sports.
Conclusions: The prevalence of tobacco use was
lower among the participants in the tobacco prevention
programme compared with the non-participants as well
as with the controls in the cohort. However, the
observed benefit of the intervention may be
overestimated as participation was biased by selection.
1
Department of Public Health
and Clinical Medicine,
Division for Occupational and
Environmental Medicine, The
OLIN Unit, Umeå University,
Umeå, Sweden
2
Department of Research,
Norrbotten County Council,
Luleå, Sweden
Correspondence to
Dr Linnéa Hedman;
[email protected]
INTRODUCTION
Smoking is the single most important and
preventable risk factor for all respiratory
symptoms and a large number of diseases.
Although the health consequences are well
known, smoking is still common.1 Daily
smoking is usually established during the
teen years, most commonly between 14 and
17 years of age,2 and rarely after the age
of 24.3 Although Sweden is often mentioned
Strengths and limitations of this study
▪ This paper presents data from a prospective
cohort study with high response rates and few
participants lost to follow-up.
▪ A validated questionnaire about asthma and
respiratory symptoms was used.
▪ Collaboration with a tobacco prevention programme (Tobacco Free Duo) enabled us to
combine the longitudinal data from the
Obstructive Lung disease in Northern Sweden
(OLIN) studies with intervention data on participation in the prevention programme.
▪ We lack information about the level of activity in
the tobacco prevention programme during the
follow-up time.
▪ Self-reported smoking was not validated by
objective measures.
as a country with a decreasing prevalence of
smokers and high quit rates among adults,4
the decrease in smoking prevalence among
teenagers has been limited.5 Therefore,
reducing smoking in teenagers is an important public health matter.
In the last decades, a wide range of prevention efforts have been carried out in order to
reduce smoking among teenagers.6–10 A key
factor for successful prevention is the longterm
collaboration
between
national,
regional and local organisations. On the
national and regional levels, smoking bans in
schools,11 and combination approaches that
include policies, media campaigns and
school-based programmes,12 have been
shown to be effective methods to decrease
smoking among adolescents. However, many
prevention efforts aimed at teenagers are voluntary and participation may be affected by
selection bias if those with the greatest need
of the intervention choose not to participate.
Among adults, it is known that the prevalence of smokers is higher among nonparticipants in questionnaire surveys regarding respiratory conditions13–15 and in health
promotion interventions.16 However, few
studies have reported on factors related to
non-participation in tobacco intervention
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Open Access
among teenagers. One available study showed that nonparticipation in a family-directed tobacco and alcohol
prevention programme was related to male sex, lower
parental education and parental smoking.17
The aim of the present study was to determine the
prevalence of tobacco use among teenagers and to
evaluate the outcome of a school-based voluntary
tobacco prevention programme for teenagers. Further,
factors related to participation in the prevention programme were investigated.
METHODS
Study population
As a part of the Obstructive Lung Disease in Northern
Sweden (OLIN) studies, a population-based paediatric
cohort was recruited in 2006. The parents to all children
in first and second grade (age 7–8 years) in three municipalities of northern Sweden: Luleå, Piteå and Kiruna,
were invited to complete a questionnaire and 2585 participated (96% of invited).18 19 Four years later, at the age
of 11–12 years, the parents were invited to a follow-up
questionnaire survey using the same methods, and 2612
completed the questionnaire (95% of invited). At the
age of 14–15 years, those who had participated in any of
the previous two surveys were reinvited (n=2657) and
2345 participated (88.3%; figure 1). In this latter survey
the questionnaire was completed by the teenagers.
The questionnaire
The questionnaire included the International Study of
Asthma and Allergies in Childhood (ISAAC) core questionnaire.20 It was expanded with additional questions
about asthma and allergic diseases including physician
diagnoses, symptoms, use of medicine and heredity.
Other questions included possible risk factors such as
living conditions, physical activity, parental smoking and
socioeconomic status (SES).19 In the questionnaire completed by the teenagers at the age of 14–15 years, questions about tobacco use were added.
The tobacco prevention programme
Tobacco Free Duo is a long-term school-based tobacco
prevention programme with the aim to prevent tobacco
Figure 1 Flow chart of the study design and participation in
a cohort study about asthma and allergic diseases, and in a
tobacco prevention programme.
2
use initiation during teen years.7 At the end of sixth
grade, a teenager had the opportunity to team up with
an adult. The pair signed a contract to stay tobacco free
for the next 3 years. The prevention programme
included information to increase knowledge and awareness on tobacco-related issues, to the teenagers as well as
to the adults. It also included an annual assurance of fulfilment of the contract after grade 7, 8 and 9, and positive reinforcements to the participants. An evaluation of
Tobacco Free Duo in Västerbotten county, Sweden,
showed significantly lower prevalence of smoking in the
intervention schools compared with control schools.7
In 2010, Tobacco Free Duo was initiated in several
municipalities in Norrbotten county, including Luleå
and Kiruna; two of the OLIN study areas. It was up to
the schools to decide whether they wanted to participate
in the prevention programme. The children in 13
schools in Kiruna (n=360) and 4 schools in Luleå
(n=87) were invited to participate by signing the contract at the age of 12 years (figure 1). A collaboration
between the OLIN studies and Tobacco Free Duo
enabled a joint database with data on participation in
the prevention programme and longitudinal questionnaire data from the OLIN studies.
Definitions
Participants: those who attended a school in the study
area that was invited to participate in Tobacco Free Duo,
and chose to sign the contract to participate at the age
of 12 years.
Non-participants: those who attended a school in the
study area that was invited to participate in Tobacco Free
Duo, but chose not to participate.
Controls: those who attended the schools in the study
area that were not invited to Tobacco Free Duo.
Snus: moist ground tobacco which is placed under the
upper lip.
Any smoking/snus use: those reporting smoking/snus
use daily, weekly or monthly. Classification of SES was
based on parental occupation according to a system
developed by Statistics Sweden.21 The highest level of
SES among the adults in the household was chosen. In
an aggregated form, the classification consisted of six
groups of occupationally active persons, and one group
of non-active persons as follows: (1) professionals and
executives; (2) self-employed; (3) intermediate nonmanual employees; (4) assistant non-manual employees;
(5) manual workers in industry; (6) manual workers in
service; (7) unemployed, including students, retired and
housewives.
Statistical analysis
Analyses were made using the computer software IBM
SPSS Statistics (V.22.0; IBM SPSS Statistics, New York,
USA). For assessment of differences between groups, χ2
tests were used and a p value <0.05 was considered statistically significant. Dependent variables were smoking
and use of snus, respectively, at the age of 15 years, and
Hedman L, et al. BMJ Open 2015;5:e007673. doi:10.1136/bmjopen-2015-007673
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participation in the tobacco prevention programme
from the age of 12 years. Independent variables
included sex, having smoking or snus-using parents,
living conditions, participation in sports and parental
SES. Significant and borderline significant factors identified in the bivariate analyses were included in multivariate analyses, which were performed by multiple logistic
regression analysis and expressed as ORs with 95% CIs.
significantly more common among boys than girls (7.2%
and 1.9%, p<0.001). The prevalence of monthly
smoking was 1.5%, weekly smoking was 0.9%, monthly
use of snus was 0.9% and weekly snus use was 0.5%.
The prevalence of daily smoking in the cohort was
3.5%, and significantly higher among the girls than
among boys (table 1). For daily snus use, the overall
prevalence was 3.3%, significantly more common among
boys. The prevalence of daily smoking and the use of
snus were both significantly lower compared with the
prevalence in a similar cohort, surveyed 10 years previously in the same study area. At that survey, the prevalence of daily smoking was 5.8% and using snus, 9.9%.9
In the present study, the prevalence of daily smoking
RESULTS
Prevalence of tobacco use at the age of 14–15 years
The prevalence of any smoking was 5.9%, with no statistical difference by sex. Any snus use was 4.7%, and
Table 1 Prevalence (%) of tobacco use in relation to demographic factors, at the age of 14–15 years
Smoking
Snus use
Bivariate analysis
Daily
smoking Difference
(%)
p value
Sex
Boys
2.7
Girls
4.4
Tobacco intervention
Control
3.5
Participant
0.9
Non-participant
4.9
Mother smoking
No
2.5
Yes
10.1
Father smoking
No
2.6
Yes
10.2
Mother using snus
No
3.1
Yes
6.7
Father using snus
No
2.5
Yes
5.8
Living conditions
House
3.1
Apartment
5.9
Both
2.6
Single parent household
7.4
Two parent household
3.0
Participation in sports
No
7.8
Yes
1.8
Parental socioeconomic status
Professionals
0.8
Self-employed
7.2
Intermediate non-manual
1.9
Assistant non-manual
3.7
Manual workers industry
5.6
Manual workers service
4.4
Unemployed
20.0
Multivariate
analysis
OR
95% CI
Bivariate analysis
Daily
use of
Difference
snus (%) p value
0.021
1.00
1.95 1.11 to 3.41
5.5
1.0
0.073
1.00
0.20 0.03 to 1.48
1.26 0.51 to 3.16
<0.001
Multivariate
analysis
OR
95% CI
<0.001
5.72 2.76 to 11.85
1.00
3.1
0.9
7.7
0.023
1.00
0.53 0.12 to 2.27
2.14 1.05 to 4.37
2.46 1.29 to 4.68
2.5
8.4
<0.001
3.38 1.76 to 6.50
<0.001
1.79 0.93 to 3.45
3.0
5.6
0.023
0.76 0.34 to 1.66
0.005
1.19 0.54 to 2.64
2.7
8.0
<0.001
1.72 0.85 to 3.48
<0.001
1.65 0.94 to 2.90
1.8
6.6
<0.001
3.20 1.81 to 5.64
0.026
2.7
6.1
1.7
6.4
2.8
0.002
<0.001
1.00
0.79 0.38 to 1.63
0.75 0.21 to 2.71
1.34 0.64 to 2.81
1.00
0.001
1.00
1.78 0.91 to 3.47
0.32 0.04 to 2.49
1.07 0.49 to 2.34
1.00
<0.001
1.00
0.30 0.17 to 0.52
4.9
2.7
0.006
1.00
0.67 0.39 to 1.18
0.005
1.00
0.90
1.25
0.75
1.58
1.63
0.80
<0.001
1.00
6.07
2.22
3.65
4.57
3.06
14.21
1.70
0.68
1.09
1.44
0.89
3.49
to 21.72
to 7.25
to 12.21
to 14.47
to 10.50
to 57.84
2.1
3.2
2.8
2.6
4.9
5.6
5.0
0.23
0.53
0.24
0.64
0.63
0.14
to 3.50
to 2.94
to 2.37
to 3.93
to 4.22
to 4.60
Significant factors in the bivariate analyses were included in a multiple logistic regression analysis and expressed as ORs with 95% CI.
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and daily use of snus, respectively, was significantly
higher among those with smoking or snus-using parents,
living in an apartment, living in a single parent household, not participating in sports and among those with
lower parental SES (table 1). There were no significant
differences in the prevalence of smoking or snus use
related to urban or rural living, having older siblings,
having physician-diagnosed asthma or a positive skin
prick test.
In a multivariate analysis, daily smoking was related to
female sex; having a smoking mother; a smoking father;
not participating in sports; and parental SES of selfemployed, assistant non-manual, manual worker in industry
and unemployed. Daily use of snus was related to male
sex, having a smoking mother and having a father who
used snus (table 1).
Participation in the tobacco prevention programme
The children in the participating schools (n=447) were
compared with children in non-participating schools
(n=2165). There were no statistically significant differences in the prevalence of male sex, parental smoking,
living conditions, physician-diagnosis of asthma, participation in sports or parental SES between the sample
invited to the tobacco prevention programme and the
controls who were not invited. However, among those
invited to the prevention programme, the prevalence of
urban living (81% vs 58%, p<0.001), and having older
siblings (67% vs 62%, p=0.047) was significantly higher
compared with the controls. Among the 447 invited to
join the prevention programme, 224 (50%) chose to
participate by signing a contract. Comparison of baseline
characteristics between participants and non-participants
in the tobacco prevention programme is presented in
table 2. Comparing non-participants with participants,
the prevalence of boys (59% vs 43%), having a smoking
mother (20% vs 9%) and living in a single parent household (16% vs 8%) was significantly higher among the
non-participants, while fewer non-participants were
taking part in sports (65% vs 79%). Among the participants, it was more common to have parental SES at the
professional and assistant non-manual level, while
among non-participants, parental SES from among intermediate non-manual and manual workers, in industry
and service level, was more common (test-for-trend
p<0.005). There were no significant differences between
participants and non-participants regarding living in a
house versus living in an apartment, urban versus rural
living, having older siblings, or having physiciandiagnosed asthma.
Significant factors related to non-participation in the
tobacco prevention programme identified in the bivariate analyses were included in a multivariate analysis.
Non-participation was related to male sex (OR 1.8, 95%
CI 1.2 to 2.7), having a smoking mother (OR 2.1, 95%
CI 1.1 to 3.8) and parental SES of manual workers in
service (OR 3.0, 95% CI 1.3 to 6.7). Participation in
sports was inversely related to non-participation (OR 0.6,
95% CI 0.3 to 0.9; table 3).
Effect of the intervention
The prevalence of smoking and use of snus was significantly lower among the participants in the prevention
programme compared with the non-participants and the
Table 2 Baseline characteristics at the age of 11–12 years among the participants and non-participants in a tobacco
prevention programme
Male sex
Smoking mother
Smoking father
Living conditions
House
Apartment
Both
Urban
Rural
Single parent household
Having older siblings
Physician-diagnosed asthma
Participation in sports
Parental socioeconomic status
Professionals
Self-employed
Intermediate non-manual
Assistant non-manual
Manual workers industry
Manual workers service
Unemployed
4
Participants n=224 (%)
Non-participants n=223 (%)
Difference p value
42.9
9.0
10.5
59.2
20.4
8.2
0.001
0.001
0.412
75.5
20.5
4.1
80.0
19.5
7.6
62.4
13.5
78.5
69.0
25.8
5.2
78.9
19.1
15.7
70.0
14.1
65.3
28.0
6.4
28.0
15.1
14.2
6.9
1.4
18.1
6.0
32.4
10.6
16.7
13.4
2.8
0.326
0.530
0.008
0.094
0.846
0.002
0.005
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Table 3 Factors related to non-participation in a tobacco
prevention programme, analysed by multiple logistic
regression and expressed as ORs with 95% CI
Non-participation
OR
95% CI
Male sex
Smoking mother
Single parent household
Participation in sports
Parental socioeconomic status
Professionals
Self-employed
Intermediate non-manual
Assistant non-manual
Manual workers industry
Manual workers service
Unemployed
1.81
2.05
1.78
0.55
1.20 to
1.09 to
0.90 to
0.34 to
2.74
3.84
3.51
0.89
1.00
1.06
1.56
0.85
1.37
2.98
2.87
0.43 to
0.90 to
0.42 to
0.70 to
1.32 to
0.25 to
2.63
2.71
1.72
2.70
6.74
33.38
controls in the rest of the cohort (figure 2). Of the participants in the programme, only four individuals were
daily smokers or snus users at the age of 14–15 years. On
the school level, there was no spill-over effect, that is,
there was no difference in tobacco use between the children at the invited schools and the control schools.
Among the controls at baseline at the age of
11–12 years, the prevalence of having a smoking
mother was 14.4%, and 11.4% had a smoking father.
In the follow-up, the corresponding proportions were
very similar: 13.4% and 12.4%, respectively. However,
among the participants in the intervention, the prevalence of having a smoking mother decreased from
Figure 2 Prevalence of tobacco use at the age of
14–15 years among participants and non-participants in the
prevention programme and among the controls in the rest of
the cohort. Test for trend: participants versus non-participants:
smoking p<0.001; snus p<0.001. Participants versus controls:
smoking p=0.007; snus p=0.026. Non-participants versus
controls: smoking p=0.054; snus p=0.002.
Hedman L, et al. BMJ Open 2015;5:e007673. doi:10.1136/bmjopen-2015-007673
9.0% to 5.8% ( p=0.201), while having a smoking father
remained similar, 10.5% and 11.5%. However, none of
these differences in prevalence were statistically
significant.
DISCUSSION
In this population-based prospective study, we report a
low prevalence of tobacco use among Swedish teenagers,
especially among the participants in a tobacco prevention programme. Further, we found that participation in
the prevention programme was affected by a selection
bias, as those in most need of smoking prevention, that
is, children having smoking parents and a lower SES, did
not participate.
From the 1980s to the 2000s, smoking steadily
decreased among Swedish adults,22 23 while the prevalence of smoking initiation among teenagers remained
relatively stable.5 However, in the last decade there have
been some reports of a decrease also among teenagers.
In 2003, the prevalence of daily smoking at the age of
14–15 years was 5.8% and using snus 9.9% in a similar
cohort in the same study area,9 compared with 3.5%
and 3.3%, respectively, in the present study. Thus,
smoking and the use of snus had both decreased, a positive result in accordance with recent nationwide reports
among Swedish5 and Norwegian teenagers.24
Despite the low prevalence of tobacco use, some teenagers were more likely to be tobacco users than others.
Smoking was related to socioeconomic factors such as
parental socioeconomic level, living in a single parent
household and living in an apartment, in accordance
with other studies.9 24–26 There are socioeconomic
inequalities in health,27 and the fact that smoking is
more common among those with lower socioeconomic
level contributes to these inequalities.24 28 Other factors
related to smoking were female sex, having smoking
family members and not taking part in sports, as shown
in other studies.9 29 30 Few studies have reported on
factors related to snus use among teenagers.9 Similar to
other studies,29 the risk factors for using snus were male
sex and parental tobacco use. Additionally, we found a
significant association between snus use and parental
SES of manual workers in industry and in service.
However, in the multivariate analysis, this association lost
significance. It has been shown that lower educational
level and income was related to snus use among adults
in Sweden.31
By identification and characterisation of tobacco users,
and also populations at risk of becoming tobacco users,
prevention efforts might be improved. Because parental
tobacco use is an important risk factor for tobacco use
among teenagers,9 29 the study design of the present
prevention programme (Tobacco free Duo) included
the partnership with a tobacco-free adult. In an evaluation of Tobacco Free Duo in another county in
Sweden, it was shown that the prevalence of smoking
not only decreased among the teenagers, but also
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among the adult participants in the programme.32 This
was also seen in our study, but the decrease was not statistically significant. Having tobacco-free role models is
an important aspect of tobacco prevention among
teenagers.
In studies among adults, non-participation in studies
about respiratory conditions is associated with higher
prevalence of smoking13 14 33 and lower SES.16 Further,
non-participation in an alcohol use prevention study
among teenagers was related to lower parental socioeconomic level.34 However, little is known about nonparticipation in smoking prevention programmes
among teenagers. In a review of the long-term effects
of smoking prevention programmes, the authors noted
a selection bias, as most reviewed programmes were
based on convenience samples and not random
samples.35 This may impact the external validity of a
study because the sample may not be representative of
the general population. Further, it has been shown that
having smoking family members decreased the efficacy
of a school-based smoking prevention programme.36
Thus, involving the family in smoking prevention seems
to be a good idea. However, although the prevention
programme in our study involved the child and an
adult, and was a collaboration between schools,
Norrbotten county council and local organisations, the
participation rate was low, as only 50% chose to join the
programme. Furthermore, the prevalence of having a
smoking mother was twice as high among the nonparticipants compared with the participants. Thus,
many of those who would have benefited from the prevention efforts chose not to participate. Another factor
related to non-participation was parental SES of
manual workers in service. One explanation for this
finding may be that manual workers in service as well
as smoking are more common among women, in this
case the mothers, and both these factors were related
to non-participation.
We suggest that in order to avoid this bias and
improve the efficacy of smoking prevention, even closer
collaboration between policymakers, community, school
and the family is needed. If we succeed in reaching and
informing these actors, the prevention strategies may
target a larger population. Further, as most of the teenagers were at a low risk of becoming smokers, the ‘prevention paradox’ may apply, similar to smoking cessation
intervention among smokers.37 It states that prevention
strategies on the population level are more likely to
reduce the smoking-related health problems in the
population compared with strategies on the individual
level. Although strategies on the individual level may
target teenagers at high risk of becoming smokers, these
individuals are relatively few and only account for a
minority of the overall public health burden. Prevention
strategies on the population level are said to be more
effective, simply because they reach a higher number of
individuals. Promising prevention strategies that have
been suggested, aimed at teenagers, include media
6
campaigns, increasing cigarette price and restricting
access to tobacco products, and also social environment
changes such as reduction of smoking among adult role
models.38
The strengths of this study included the longitudinal
study design, with high response rates, few participants
lost to follow-up and the use of validated questionnaires.
Further, the collaboration with the prevention programme, Tobacco Free Duo, enabled us to combine the
longitudinal data from the OLIN studies with intervention data on participation in the prevention programme.
A limitation of the study included the lack of information about the level of activity in the tobacco prevention
programme during the follow-up time. Another limitation is that self-reported smoking was not validated by
objective measures. However, others that compared selfreports of smoking with cotinine levels in saliva found
good agreement.39
In conclusion, prevalence of tobacco use was significantly lower among the participants in the tobacco prevention programme compared with the controls, after
3 years. However, the observed benefit of the intervention may be overestimated as the participation was
related to a selection bias, as those in most need of
smoking prevention, that is, children having smoking
parents and a lower SES, did not participate. One way to
improve the efficacy of smoking prevention efforts is to
have even closer collaboration between policymakers,
community, school and the family. Developing comprehensive strategies for including more high-risk children
in prevention efforts at the population level will be an
important measure to reduce tobacco use among
teenagers.
Acknowledgements Sigrid Sundberg, Sven-Arne Jansson, Pia Johansson
and Bodil Larsson are acknowledged for data collection.
Contributors LH was responsible for the study design, collected the
data, performed the statistical analyses, drafted and revised the
manuscript, and approved the final manuscript. MA and CS contributed to
the analysis and interpretation of data, reviewed and revised the
manuscript, and approved the final manuscript. ER was responsible for
study conception and design, contributed to the analysis and interpretation
of data, reviewed and revised the manuscript, and approved the final
manuscript.
Funding This work was supported by The Swedish Heart-Lung Foundation
(grant number 20100307); The Swedish Asthma-Allergy Foundation (grant
number 2013036); Visare Norr (grant number 217341); and Norrbotten
County Council.
Competing interests None declared.
Ethics approval The Regional Ethical Review Board at Umeå University,
Sweden.
Provenance and peer review Not commissioned; externally peer reviewed.
Data sharing statement No additional data are available.
Open Access This is an Open Access article distributed in accordance with
the Creative Commons Attribution Non Commercial (CC BY-NC 4.0) license,
which permits others to distribute, remix, adapt, build upon this work noncommercially, and license their derivative works on different terms, provided
the original work is properly cited and the use is non-commercial. See: http://
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Evaluation of a tobacco prevention
programme among teenagers in Sweden
Linnéa Hedman, Martin Andersson, Caroline Stridsman and Eva
Rönmark
BMJ Open 2015 5:
doi: 10.1136/bmjopen-2015-007673
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